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Thermal-Hydrological-Mechanical Modelling of Stockton University Reservoir Cooling System, Fine Scale Stress Test Modelling

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Mesh, properties, initial conditions, injection/withdrawal rates for modelling thermal, hydrological, and mechanical effects of fluid injection to and withdrawal from ground for Stockton University reservoir cooling system (aquifer storage cooling system), Galloway, New Jersey, for unscheduled two hour injection at 133 % designed capacity, on fine scale grid, with some results. Second simulation of J.T. Smith, E. Sonnenthal, P. Dobson, P. Nico, and M. Worthington, 2021. Thermal-hydrological-mechanical modeling of Stockton University reservoir cooling system, Proceedings of the 46th Workshop on Geothermal Reservoir Engineering, Stanford University, SGP-TR-218, from which Figures 6-9, pertain.

File Overview.txt

An over view of files in this submission.
79

GENER.2well.stresstest.halfsrcs

TReactMech GENER file (a text file). Fluid source and sink terms in TOUGH2 GENER file format. Sources and sinks are separate entries. For each source after line with el... more
58

MESH.stoctonloc.3.1.noflowymax.zip

(Zipped) TReactMech MESH file. Grid information in TOUGH2 MESH file format. Elements are in x,z,y order; x varying fastest, z next, and y last; i.e., in successive vert... more
26

Plasticity.tec

TReactMech mechanical failure output file, at all times. (a text file.) At each time, a header, then X(m), Y(m), Z(m), ielem, N_shear, N_tensl, N_Surf, E_fail_xx, E_... more
85

SAVE.1.67e12s.zip

(Zipped) TReactMech INCON file (a text file) (TOUGH2 compatible). Initial pressure and temperature by element name. File alternates lines of element name (with porosity... more
24

T-H-M Modeling of Stockton Univ. Reservoir Cooling System

J.T. Smith, E. Sonnenthal, P. Dobson, P. Nico, and M. Worthington, 2021. Thermal-hydrological-mechanical modeling of Stockton University reservoir cooling system, Proce... more

TOUGH2 User's Guide Version 2

K. Pruess, C. Oldenburg, and G. Moridis, 2012. TOUGH2 User's Guide, Version 2, Lawrence Berkeley National Laboratory, LBNL-43134.

TReactMech_mech_3D_inp_format.txt

Program TReactMech mech_3D.inp input file keyword format descriptions.
93

displacement.03.tec.zip

(Zipped) TReactMech mechanics displacement output file (after two hours injection). (a tecplot file, text file.) element corner x,y,z (m), x displacement (m), y displac... more
21

flow.stockton.8layloc.inp

Program TReactMech flow.inp input file (a text file). Global and local flow parameters. Local parameters organized by (MESH file) rock type. Formats for individual item... more
59

flowdata003.tec.zip

(Zipped) TReactMech flow data output file (after two hours injection). (a tecplot file, text file.) Element center x,y,z, pressure, temperature, gas saturation, liquid ... more
24

initialstress_sand0.5029_clay0.7003_1.zip

(zipped) TReactMech initial stress file (a text file). Format described in file TReactMech_mech_3D_inp_format.txt. Units are Pa.
24

mech_3D.stockton.7lay.notensclay.updated.inp

Program TReactMech mech_3D.inp input file, (a text file). Global and local mechanics parameters. Local parameters organized by (MESH file) rock type. Structure describe... more
44

stress_strain.03.tec.zip

(Zipped) TReactMech mechanics stress and strain output file (after two hours injection). (a tecplot file, text file.) "X(m)", "Y(m)", "Z(m)", "Sigma_xx", "Sigm... more
22

Citation Formats

TY - DATA AB - Mesh, properties, initial conditions, injection/withdrawal rates for modelling thermal, hydrological, and mechanical effects of fluid injection to and withdrawal from ground for Stockton University reservoir cooling system (aquifer storage cooling system), Galloway, New Jersey, for unscheduled two hour injection at 133 % designed capacity, on fine scale grid, with some results. Second simulation of J.T. Smith, E. Sonnenthal, P. Dobson, P. Nico, and M. Worthington, 2021. Thermal-hydrological-mechanical modeling of Stockton University reservoir cooling system, Proceedings of the 46th Workshop on Geothermal Reservoir Engineering, Stanford University, SGP-TR-218, from which Figures 6-9, pertain. AU - Smith, J Torquil A2 - Sonnenthal, Eric A3 - Dobson, Patrick A4 - Nico, Peter A5 - Worthington, Mark DB - Open Energy Data Initiative (OEDI) DP - Open EI | National Renewable Energy Laboratory DO - 10.15121/1843041 KW - geothermal KW - cooling KW - thermal-hydrological-mechanical KW - modeling KW - ground source KW - stress test KW - stress modeling KW - model KW - stress KW - injection KW - withdrawal KW - fluid KW - simulation KW - aquifer storage cooling system KW - reservoir cooling system KW - Stockton University KW - New Jersey KW - geothermal cooling KW - CFD KW - flow simulation KW - FEA LA - English DA - 2021/02/22 PY - 2021 PB - Lawrence Berkeley National Laboratory T1 - Thermal-Hydrological-Mechanical Modelling of Stockton University Reservoir Cooling System, Fine Scale Stress Test Modelling UR - https://doi.org/10.15121/1843041 ER -
Export Citation to RIS
Smith, J Torquil, et al. Thermal-Hydrological-Mechanical Modelling of Stockton University Reservoir Cooling System, Fine Scale Stress Test Modelling. Lawrence Berkeley National Laboratory, 22 February, 2021, GDR. https://doi.org/10.15121/1843041.
Smith, J., Sonnenthal, E., Dobson, P., Nico, P., & Worthington, M. (2021). Thermal-Hydrological-Mechanical Modelling of Stockton University Reservoir Cooling System, Fine Scale Stress Test Modelling. [Data set]. GDR. Lawrence Berkeley National Laboratory. https://doi.org/10.15121/1843041
Smith, J Torquil, Eric Sonnenthal, Patrick Dobson, Peter Nico, and Mark Worthington. Thermal-Hydrological-Mechanical Modelling of Stockton University Reservoir Cooling System, Fine Scale Stress Test Modelling. Lawrence Berkeley National Laboratory, February, 22, 2021. Distributed by GDR. https://doi.org/10.15121/1843041
@misc{OEDI_Dataset_7476, title = {Thermal-Hydrological-Mechanical Modelling of Stockton University Reservoir Cooling System, Fine Scale Stress Test Modelling}, author = {Smith, J Torquil and Sonnenthal, Eric and Dobson, Patrick and Nico, Peter and Worthington, Mark}, abstractNote = {Mesh, properties, initial conditions, injection/withdrawal rates for modelling thermal, hydrological, and mechanical effects of fluid injection to and withdrawal from ground for Stockton University reservoir cooling system (aquifer storage cooling system), Galloway, New Jersey, for unscheduled two hour injection at 133 \% designed capacity, on fine scale grid, with some results. Second simulation of J.T. Smith, E. Sonnenthal, P. Dobson, P. Nico, and M. Worthington, 2021. Thermal-hydrological-mechanical modeling of Stockton University reservoir cooling system, Proceedings of the 46th Workshop on Geothermal Reservoir Engineering, Stanford University, SGP-TR-218, from which Figures 6-9, pertain.}, url = {https://gdr.openei.org/submissions/1363}, year = {2021}, howpublished = {GDR, Lawrence Berkeley National Laboratory, https://doi.org/10.15121/1843041}, note = {Accessed: 2025-07-22}, doi = {10.15121/1843041} }
https://dx.doi.org/10.15121/1843041

Details

Data from Feb 22, 2021

Last updated Feb 1, 2022

Submitted Feb 1, 2022

Organization

Lawrence Berkeley National Laboratory

Contact

J Torquil Smith

jtsmith@lbl.gov

501.549.3817

Authors

J Torquil Smith

Lawrence Berkeley National Laboratory

Eric Sonnenthal

Lawrence Berkeley National Laboratory

Patrick Dobson

Lawrence Berkeley National Laboratory

Peter Nico

Lawrence Berkeley National Laboratory

Mark Worthington

Underground Energy Systems LLC

Research Areas

DOE Project Details

Project Name Community Resilience through Low-Temperature Geothermal Reservoir Thermal Energy Storage

Project Lead Arlene Anderson

Project Number FY21 AOP 2.7.1.4

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